Regulation of the higher-order structure of chromatin by histones H1 and H5

Chicken erythrocyte chromatins containing a single species of linker histone, H1 or H5, have been prepared, using reassembly techniques developed previously. The reconstituted complexes possess the conformation of native chicken erythrocyte chromatin, as judged by chemical and structural criteria; saturation is reached when two molecules of linker histone are bound per nucleosome, as in native erythrocyte chromatin, which the resulting material resembles in its appearance in the electron microscope and quantitatively in its linear condensation factor relative to free DNA. The periodicity of micrococcal nuclease-sensitive sites in the linker regions associated with histone H1 or H5 is 10.4 base pairs, suggesting that the spatial organization of the linker region in the higher-order structure of chromatin is similar to that in isolated nucleosomes. The susceptible sites are cut at differing frequencies, as previously found for the nucleosome cores, leading to a characteristic distribution of intensities in the digests. The scission frequency of sites in the linker DNA depends additionally on the identity of the linker histone, suggesting that the higher-order structure is subject to secondary modulation by the associated histones.     

Nucleosomes containing histones H1 or H5 are closely interspersed in chromatin

The distribution of histones H1 and H5 along chromatin fibers has been examined in the nucleated hen erythrocyte. Nucleosome oligomers, produced by micrococcal nuclease digestion of nuclei, were sequentially reacted with affinity-chromatography purified rabbit anti-H5 and sheep anti-rabbit antibodies. Quantitation of the relative amounts of H1 and H5 in the precipitated and supernatant fractions as a function of the oligomer number was consistent with a close interspersion of both types of histones, probably a random one. This conclusion was supported by the immunoprecipitation of longer chromatin fibers. This pattern of distribution appears to apply both to bulk chromatin and to chromatin inactivated during the maturation of the erythrocyte.     

Roles of H1 domains in determining higher order chromatin structure and H1 location

Peptides derived from calf thymus H1 and rat liver H1, comprising only the globular and COOH-terminal domains of the intact molecule and therefore lacking NH2-terminal domains, have been shown by reconstitution to be as effective as the complete H1 molecule in inducing higher-order-chromatin structure. As the globular domain of H1 alone cannot induce chromatin folding, our results demonstrate that this function is primarily controlled by the COOH-terminal domain of the molecule. Surprisingly, these peptides do not locate correctly with respect to the nucleosome. This is demonstrated by their failure to confer upon reconstitutes the ability to protect DNA fragments of chromatosome length when digested with micrococcal nuclease. The precise placement of the H1 molecule (globular domain) with respect to the nucleosome is shown to be influenced by the "tail" domains of both H1 and the core histones.     

Radioiodination of chicken erythrocyte histones H4 and H5 in chromatin.

The conformational state of histones in isolated chicken erythrocyte chromatin was studied using procedures developed for probing surface proteins on membranes. Under controlled conditions, only exposed tyrosyl residues react with iodide radicals, generated either by the oxidant, chloramine-T (paratoluenesulfonyl chloramide), or the enzyme lactoperoxidase, giving monoidotyrosine. Using 125-iodine, this study compared the reactive tyrosines in free and bound histones H4, and H5. The relative extent of iodination of these histones within (H4) and outside (H5) of the nucleosomes was measured after extraction and gel electrophoresis. Each of the histones was further analyzed for the extent of specific tyrosine iodination by separating the tryptic peptides by high voltage electrophoresis. The identity of the labeled peptide was determined by dansylation of the amino acids present in each hydrolyzed peptide. The results show that there is a difference in the conformational arrangement of these histones on chromatin and in the free forms, since in chromatin not all tyrosine residues are as accessible for iodination as in the denatured state. Residue 53 of histone H5 for instance is more reactive than residues 28 and 58, indicating that the segments containing the latter residues are involved in either protein-DNA or protein-protein interactions. In histone H4, preferential labeling of 2 of the 4 tyrosines present was also observed.     

One-step fractionation method for isolating H1 histones from chromatin under nondenaturing conditions

By combining conventional methods of chromatin preparation with ion-exchange chromatography in CM-Sephadex C-25, we have been able to isolate and fractionate histone H1 variants from different sources. This method of fractionation is very simple and allows one to obtain, very rapidly, large amounts of these histones in a native nondenatured conformation.     

Accessibility of the globular domain of histones H1 and H5 to antibodies upon folding of chromatin

Antibodies to the globular domain of histones H1 and H5 were purified by affinity chromatography and used to study the accessibility of this region of H1 and H5 in folded and unfolded rat liver and hen erythrocyte chromatin respectively. The different conformations of the chromatin filament were induced by varying the ionic strength from 1 mM to 80 mM NaCl and maintained by fixation with glutaraldehyde. Treatment with glutaraldehyde at a given salt concentration affected neither the orientation of nucleosomes relative to the fiber axis nor the compactness of chromatin. Solid-phase immunoassay and inhibition experiments showed no binding of the antibody against the globular domain of H1 to chromatin at the entire range of salt concentrations, while the antibody to the whole H1 molecule reacted with chromatin at low salt. On the other hand, the antibody to the globular region of H5 reacted with hen erythrocyte chromatin independently of the extent of chromatin condensation. These results indicate that the antigenic determinants of the globular domain of H5 are accessible to the antibody both in folded and unfolded chromatin, while those of the same region of H1 are masked, probably by interaction with DNA or proteins.     

Modification of the lysine residues of histones H1 and H5: Effects on structure and on the binding to chromatin

The extensive modification of histone H1 from calf thymus with the amino-group reagent dimethylmaleic anhydride (over 35 lysine residues modified per molecule) produces no effect on its secondary structure detectable by circular dichroism (far UV). Fluorescence and circular dichroism (near-UV) of the modified histone show variations in the local environment of its sole tyrosine residue. These changes are reversed on regeneration of the modified amino groups. While histone H1 is easily dissociated with this reagent from calf thymus or chicken erythrocyte chromatin, a much stronger treatment is needed to liberate histone H5 from erythrocyte chromatin. This difference appears to be related to the higher arginine content of histone H5.     

Phosphorylation of H1 histones

The phosphorylation of H1 histones is reviewed. Consideration is given to phosphorylation reactions which occur in both replicating and nonreplicating cells. The available evidence suggests that H1 histones accept phosphate groups at different sites in response to different stimuli. The tentative location of the acceptor sites is summarized, and the effects of site-specific phosphorylation on the conformation of H1 histones in vitro is discussed. The phosphorylation of H1 histones which occurs during cell replication is reviewed in detail, and it is concluded that there is no clocklike mechanism which couples the phosphorylation of a particular site or region in H1 histones to a set point in the cell cycle. There is both species-and cell-specific variability in the phosphorylation of H1 histones during cell replication. Recent studies are discussed which show that an interspecific somatic cell hybrid of mouse and Chinese hamster can replicate the Chinese hamster genome in a stable manner using only mouse H1 histones and their phosphorylated forms. I speculate that H1 histone phosphorylation is a mechanism for the relaxation of long-term structures needed for differential gene activity in order to attain the short-term goal of genome replication.     

Heterogeneity of chromatin subunits in vitro and location of histone H1.

Chromatin subunits ("nucleosomes") which were purified by sucrose gradient centrifugation of a staphylococcal nuclease digest of chromatin have been studied. We found that such a preparation contains nucleosomes of two discrete types which can be separated from each other by polyacrylamide gel electrophoresis. Nucleosome of the first type contains all five histones and a DNA segment of approximately 200 base pairs long, whereas nucleosome of the second type lacks histone H1 and its DNA segment is approximately 170 base pairs long, i.e., about 30 base pairs shorter than the DNA segment of the nucleosome of the first type. Purified dimer of the nucleosome also can be fractionated by gel electrophoresis into three discrete bands which correspond to dinucleosomes containing two molecules of histone H1, one and no H1. These and related findings strongly suggest that the H1 molecule is bound to a short (approximately 30 base pairs) terminal stretch of the nucleosomal DNA segment which can be removed by nuclease (possibly in the form of H1-DNA complex) without any significant disturbance of main structural features of the nucleosome.     

Specific degradation of histones H1 and H3

It is shown that acid treated histones H1 and H3 are susceptible to specific degradation by an associated acid resistant protease. Dialysis against distilled water (pH 5.5–6) of the acid treated histones enhances proteolysis. On the other hand, no degradation is observed in nucleohistone either in the presence of Ca⁺⁺ or Na⁺⁺ ions. The conditions required to avoid degradation during nucleohistone and histone manipulation are described.     

In vitro poly(ADP-ribosyl)ated histones H1a and H1t modulate rat testis chromatin condensation differently

Rat testis H1 proteins were poly(ADP-ribosyl)ated in vitro. The modifying product, poly(ADP-ribose), was found covalently bound to each histone variant at various extents and exhibited distinct structural features (linear and short, rather than branched and long chains). Interest was focused on the somatic H1a, particularly abundant in the testis, as compared with other tissues, and the testis-specific H1t, which appears only at the pachytene spermatocyte stage of germ cell development. These H1s were modified with poly(ADP-ribose) by means of two in vitro experimental approaches. In the first system, each variant was incubated with purified rat testis poly(ADP-ribose)polymerase in the presence of [(32)P] NAD. In parallel, poly(ADP-ribosyl)ated H1s were also prepared following incubation of intact rat testis nuclei with [(32)P] NAD. In both experiments, the poly(ADP-ribosyl)ated proteins were purified from the native forms by means of phenyl boronic agarose chromatography. The results from both analyses were in agreement and showed qualitative differences with regard to the poly(ADP-ribose) covalently associated with H1a and H1t. Comparison of the bound polymers clearly indicated that the oligomers associated with H1a were within 10-12 units long, whereas longer chains (相似文献   

Condensation of DNA and chromatin by histones H1, H5 and protamines. The influence of a protein phosphorylation

A mutual displacement of the DNA crosslinking protiens, protamines, histones H1 and H5, is observed if cell nuclei are incubated in solutions containing one of these species. While their competition is in accord with their specific positive charge, a displacement of the core histones does not occur. Crosslinking proteins give rise to the formation of macrocomplexes from DNA and core particles, respectively which in the present study are investigated by stray-light and centrifugation methods. It is shown than the reduction of electrostatic affinities, which in vivo is achieved by a protein phosphorylation, serves to enhance complex sizes, probably by permitting at thermodynamically controlled, ordered association of DNA segments.     

Psoralen-crosslinking of soluble and of H1-depleted soluble rat liver chromatin

We purified soluble rat liver chromatin and H1-depleted chromatin and photocrosslinked its DNA with psoralen at pH 7. Digestion of this chromatin with micrococcal nuclease produced a normal nucleosomal repeat. Chromatin was photoreacted in the presence of 0 to 700 mM-NaCl and was fractionated in sucrose gradients containing the same NaCl concentrations. The dissociation of H1 occurred as in the non-crosslinked controls and no preferential dissociation of core histones was observed. The samples between 100 and 500 mM-NaCl showed precipitation. In the electron microscope, the fibers appeared indistinguishable from the controls at low ionic strength. In the presence of 40 mM-NaCl, the fibers of the photoreacted chromatin were slightly more compact than the controls, and at 500 mM-NaCl, despite the complete dissociation of H1, there were still apparently intact fibers at this ionic strength. The disruption of the psoralen-treated chromatin fibers occurred only in 600 mM-NaCl, as opposed to 500 mM-NaCl in controls. The DNA of all the photoreacted samples was spread for electron microscopy under denaturing conditions. They revealed, for all the samples, single-stranded bubbles corresponding to 200 to 400 base-pairs in size. H1-depleted chromatin containing stoichiometric amounts of core histones was photoreacted at pH 10 and very low ionic strength. Under these conditions many of the nucleosomes appeared to be unraveled, although to a variable extent. In the electron microscope, the purified DNA from these samples showed extensive crosslinking when spread under denaturing conditions. These observations show that histone-DNA interactions different from those in intact nucleosomes may be created, which allow extensive access of psoralen to the DNA.     

Footprinting of linker histones H5 and H1 on the nucleosome.

DNase I has been used to footprint the linker histones H5 and H1 on the nucleosome of chicken erythrocyte chromatin. Rate constants have been derived for digestion at the principal sites of attack on chromatosome length DNA (168 bp), located about 10 bp apart, and compared with those observed for linker histone-depleted chromatosomes. Complete protection was found for site S7 on the dyad axis and decreasing partial protection seen at symmetrically positioned sites on each side of S7. Strong, but not complete protection was noted at S14, the site corresponding to the end of the core particle, situated less than 1/4 of a turn away from the dyad. Uniform partial protection was observed for sites S2, S3, S4 and S10, S12 on the far side of the chromatosome. The simplest interpretation of these results is that the globular domain of H5/H1 is responsible for the protection at S7, whilst extended N- and C-domains give rise to the partial protection at sites away from the dyad axis.